1. O.Pronitchev Argonne HPR system Contamination

2. Problem Upon removal of the filter that is at the bottom of the spray nozzle for the Argonne HPR System a Brown Contaminant was found Additional filter was added after high pressure manifold. New manifolds were manufactured and installed. After running of 1500 gallons of DI water through the additional filter in Argonne HPR system with Pump On filter color changed. Filter that is at the bottom of the spray nozzle stays white.

4. HPR system in Argonne

5. HPR system in IB4

6. New versions of manifolds were made in September 2009 by Holland Applied Technologies.

7. Supplier manufacturing drawing

8. Weld log with inspection report

9. Weld acceptance / rejection criteria ASME BPE-2005, Bioprocessing equipment

10. Material certificates

11. Manifolds were electropolished and passivated by ABLE Electropolishing

12. Pump certificates

13. ASTM A 380-06 Standard Practice for Cleaning, Descaling, and Passivation of Stainless Steel Parts, Equipment, and Systems. ASTM A 967 Chemical Passivation Treatments for Stainless Steel Parts ASTM A380 covers recommendations and precautions for cleaning descaling, and passivating of new stainless steel parts, assemblies and installed systems. More in “Surface Cleaning, Finishing, and Coating” ASM Metals Handbook. Design Precleaning Descaling Cleaning/Passivation Inspection

15. Additional filter was installed before low pressure manifold. No filter discoloration after 95 hours of HPR at 2.5 g/min (14250 gallons at 1350 psi).

16. Suspected Contaminant Source - Microbiologically Influenced Corrosion Microbiologically Influenced Corrosion is a is corrosion caused or promoted by microorganisms. It can apply to both metals and non-metallic materials.

17. Iron-related bacteriaSulfate Reducing Bacteria MIC-related bacterial growth typically occurs in systems within specific temperature ranges, depending on the type of bacteria; an “ideal” range is often reported as 4° to 49°C. Bacterial growth typically hibernates below 4°C. Some types of bacteria favor other temperature ranges; for example, most common strains of SRB grow best at 25° to 35°C. A few thermophillic types of SRB grow more efficiently at more than 60°C, and one type is capable of growing at more than 100°C. While MIC more favorably grows in their typical temperature ranges, growth in other temperature ranges should not be discounted. MIC has been found in extremely cold environments such as freezers or piping systems of Alaskan villages north of the Arctic Circle.

18. Environmental Microbiology Lab test We have send contaminated and clean filter to EMSL lab for detection of bacteria known to cause or accelerate corrosion in stainless steel. Sulfate Reducing Bacteria chemically reduce sulfates to sulfides, producing compounds such as hydrogen sulfide (H2S), or iron sulfide (Fe2S) in the case of ferrous metals. Iron-related bacteria are bacteria that derive the energy they need to live and multiply by oxidizing dissolved ferrous iron. Slime-Forming Bacteria is the name given to bacteria that are able to produce copious amounts of slime. These are commonly seen as condensed cloudy/plate-like growths suspended in the liquid medium, gel-like rings (around the ball) or globular/swirl forms of slime in the basal cone.

19. Bacteria detection test results

20. Basic Material ID Anallyses Stereomicroscope image (10x) PLM image (150x) of the material from the contaminated filter sample showing color and morphology

21. Basic Material ID Analyses SEM/EDX elemental analysis of the material from the sample filter. The combination of iron (Fe), nickel (Ni) and chromium (Cr) is indicative of stainless steel oxides. The combination of phosphorous (P), sulfur (S), potassium (K), sodium (Na) and Magnesium (Mg) are indicative of salts and other minerals. The combination of aluminum (Al) and silicon (Si) and oxygen (O) may indicate clays or grinding/polishing compounds. The high percentage of carbon (C) may me from a biological source such as bacteria, mold, or algae.

22. Stainless steel residual contaminations

23. Old manifolds internal surface inspection Weld quality not acceptable, pits, Heat tint, rough surface.

24. Pitting corrosion or Weld Metal Defect (C.Cooper)

26. SEM Image of Stainless Steel Corrosion Pit from PMET’s Materials Characterization Laboratory

27. EDS Analyses of Argonne manifold defect done by C.Cooper EDX Analysis of Corrosion Pit from PMET’s Materials Characterization Laboratory SClCrFeZn 3.80%1.10%3.40%89.50%2.10% SpectrumIn stats.COCrFeNiMoTotal Spectrum 1Yes2.511.420.263.210.52.3100 Spectrum 2Yes4.223.219.262.910.5 100 Max. 4.223.220.263.210.52.3 Min. 2.511.419.262.910.50

28. Control of passive layer Renewable contamination source

29. SUMMARY: Rig system and fill with high purity water; Establish circulation and inspect for system integrity; Formulate cleaning chemistry; Circulate cleaning chemistry at temperature; Adjust pH of cleaning chemistry; Drain and rinse system with high purity water; Fill system with high purity water and formulate passivation chemistry; Circulate passivation chemistry at temperature; Adjust pH of passivation chemistry; Drain and rinse system with high purity water to achieve conductivity parity; Perform final inspection and return system to starting configuration. High Purity Systems Cleaning and Passivation

30. Benefits of Passivation Average composition of 316L stainless steel Ratio of chrome to iron in the base metal is 0.24. By chemically treating the surface of the stainless steel, such that iron is removed, then the ratio of chrome to iron is increased. With a good passivation procedure, elemental chrome to iron ratios in the range of 0.75 to 2.0 can be attained. Reducing iron content at the surface, while leaving chrome, results in a "chromium rich“ surface, which is less likely to form corrosion products. The "chromium rich" or passive layer is found to be extremely thin - not more than 50 angstroms in depth.

31. Stainless steel corrosion in High Purity Water Systems

32. Stainless steel corrosion in Argonne HPR system

33. MINNCARE® COLD STERILANT (EPA Reg. No. 52252-4) Current maintenance procedure: 1.Sanitize with 1 – 2% Minncare solution every 12 month 2.Replace first filter every month, second filter every 6 month. 3.Rinse with DI water

34. Next steps Inspect internal surfaces of pump heads and manifolds at Argonne for signs of corrosion or surface contamination. Clean and passivate both manifolds and High Pressure pump heads on-site or off-site if needed. Coat internal surfaces with Tantaline solution (surface alloy technology that create an extremely rugged, uniform, inert and corrosion resistant tantalum surface).* *No indication that HPR system is degrading cavity performance.